Abstract
A plantigrade foot with a large robust calcaneus is regarded as a distinctive morphological feature of the human foot; it is presumably the result of adaptation for habitual bipedal locomotion. The foot of the Japanese macaque, on the other hand, does not have such a feature, which hampers it from making foot–ground contact at the heel during bipedal locomotion. Understanding how this morphological difference functionally affects the generation of bipedal locomotion is crucial for elucidating the evolution of human bipedalism. In this study, we constructed a forward dynamic simulation of bipedal locomotion in the Japanese macaque based on a neuromusculoskeletal model to evaluate how virtual manipulation of the foot structure from digitigrade to plantigrade affects the kinematics, dynamics, and energetics of bipedal locomotion in a nonhuman primate whose musculoskeletal anatomy is not adapted to bipedalism. The normal bipedal locomotion generated was in good agreement with that of actual Japanese macaques. If, as in human walking, the foot morphology was altered to allow heel contact, the vertical ground reaction force profile became double-peaked and the cost of transport decreased. These results suggest that evolutionary changes in the foot structure were important for the acquisition of human-like efficient bipedal locomotion.
Highlights
A plantigrade foot with a large robust calcaneus is regarded as a distinctive morphological feature of the human foot; it is presumably the result of adaptation for habitual bipedal locomotion
Webber and Raichlen[27] studied human walking with foot-ground contact with the balls of the foot initially with heel contact occurring later in the step and noted that the decrease in the energetic cost occurred in human walking with heel contact because of the increase in the effective limb length owing to the larger anterior translation of the center of pressure (COP)
The force profiles did not match each other exactly, the simulated results generally agreed with the measured data and captured the main features of the ground reaction force (GRF) profiles in the Japanese macaque, such as the single-peaked vertical GRF profile with a peak occurring in the early stance phase, the breaking peak magnitude being slightly larger than that for propelling, and the breaking period being shorter than the propelling period[31]
Summary
A plantigrade foot with a large robust calcaneus is regarded as a distinctive morphological feature of the human foot; it is presumably the result of adaptation for habitual bipedal locomotion. As in human walking, the foot morphology was altered to allow heel contact, the vertical ground reaction force profile became double-peaked and the cost of transport decreased These results suggest that evolutionary changes in the foot structure were important for the acquisition of human-like efficient bipedal locomotion. Webber and Raichlen[27] studied human walking with foot-ground contact with the balls of the foot initially with heel contact occurring later in the step and noted that the decrease in the energetic cost occurred in human walking with heel contact because of the increase in the effective limb length owing to the larger anterior translation of the center of pressure (COP) These findings suggested the possible functional significance of the evolution of the plantigrade foot to allow bipedal locomotion with heel contact, as observed in humans. Utilizing a generalized quadrupedal primate such as the macaque that is lessspecialized in terms of locomotor anatomy[35] as a living model of the hypothetical protohominids is of increasing importance to clarifying and reconstructing the evolution of bipedal locomotion in the early hominins
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